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TITLE / Potential role of imaging in assessing harmful effects on spermatogenesis in adult testes with varicocele
AUTHOR(s) / Athina C Tsili, Olga N Xiropotamou, Anastasios Sylakos, Vasilios Maliakas, Nikolaos Sofikitis, Maria I Argyropoulou
CITATION / Tsili AC, Xiropotamou ON, Sylakos A, Maliakas V, Sofikitis N, Argyropoulou MI. Potential role of imaging in assessing harmful effects on spermatogenesis in adult testes with varicocele. World J Radiol 2017; 9(2): 34-45
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OPEN ACCESS / This article is an open-access article which was selected by an in-house editor and fully peer-reviewed by external reviewers. It is distributed in accordance with the Creative Commons Attribution Non Commercial (CC BY-NC 4.0) license, which permits others to distribute, remix, adapt, build upon this work non-commercially, and license their derivative works on different terms, provided the original work is properly cited and the use is non-commercial. See:
CORE TIP / Varicocele is known as one of the main causes of male infertility. However, many controversies exist regarding the effect of varicocele on male reproductive potential, which patients to treat and whether repair leads to an improvement of the fertility status. Non-invasive imaging modalities, including functional sonography and magnetic resonance imaging, might provide useful information on the early damage of testicular structure by varicoceles, therefore helping clinicians target repair efforts to those men who will benefit from varicocele treatment.
KEY WORDS / Varicocele; Spermatogenesis; Diagnostic imaging; Ultrasonography; Doppler ultrasound imaging; Magnetic resonance imaging; Functional
COPYRIGHT / © The Author(s) 2017. Published by Baishideng Publishing Group Inc. All rights reserved.
NAME OF JOURNAL / World Journal of Radiology
ISSN / 1949-8470 (online)
PUBLISHER / Baishideng Publishing Group Inc, 8226 Regency Drive, Pleasanton, CA 94588, USA
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REVIEW

Potential role of imaging in assessing harmful effects on spermatogenesis in adult testes with varicocele

Athina C Tsili, Olga N Xiropotamou, Anastasios Sylakos, Vasilios Maliakas, Nikolaos Sofikitis, Maria I Argyropoulou

Athina C Tsili, Olga N Xiropotamou, Vasilios Maliakas, Maria I Argyropoulou, Department of Clinical Radiology, University of Ioannina, Medical School, University Campus, 45110 Epirus, Greece

Anastasios Sylakos, Nikolaos Sofikitis, Department of Urology, University of Ioannina, Medical School, University Campus, 45110 Epirus, Greece

Author contributions:Tsili AC and Xiropotamou ON contributed equally to this work; Tsili AC, Sofiktis N and Argyropoulou MI designed the research; Xiropotamou ON, Sylakos A and Maliakas V performed the research and analyzed the data; Tsili AC and Xiropotamou ON wrote the paper; all authors approved the final version of the article to be published.

Correspondence to:Athina C Tsili, MD, Assistant Professor, Department of Clinical Radiology, University of Ioannina, Medical School, University Campus, Ioannina, 45110 Epirus, Greece.

Telephone: +30-69-76510904 Fax: +30-26-51007862

Received: August 10, 2016 Revised:November 2, 2016 Accepted:December 16, 2016

Published online: February 28, 2017

Abstract

Varicocele is characterized by an abnormal dilatation and retrograde blood flow in the spermatic veins. Varicocele is the leading correctable cause of male infertility. Although it is highly prevalent in infertile men, it is also observed in individuals with normal fertility. Determining which men are negatively affected by varicocele would enable clinicians to better select those men who will benefit from treatment. To assess the functional status of the testes in men with varicocele, color Doppler sonographic parameters were evaluated. Testicular arterial blood flow was significantly reduced in men with varicocele, reflecting an impairment of spermatogenesis. An improvement in the testicular blood supply was found after varicocelectomy on spectral Doppler analysis. Testicular contrast harmonic imaging and elastography might improve our knowledge about the influence of varicocele on intratesticular microcirculation and tissue stiffness, respectively, providing possible information on the early damage of testicular structure by varicocele. Magnetic resonance imaging (MRI), with measurement of apparent diffusion coefficient has been used to assess the degree of testicular dysfunction and to evaluate the effectiveness of varicocele repair. Large prospective studies are needed to validate the possible role of functional sonography and MRI in the assessment of early defects of spermatogenesis in testes with varicocele.

Key words:Varicocele; Spermatogenesis; Diagnostic imaging; Ultrasonography; Doppler ultrasound imaging; Magnetic resonance imaging; Functional

© The Author(s) 2017. Published by Baishideng Publishing Group Inc. All rights reserved.

Core tip: Varicocele is known as one of the main causes of male infertility. However, many controversies exist regarding the effect of varicocele on male reproductive potential, which patients to treat and whether repair leads to an improvement of the fertility status. Non-invasive imaging modalities, including functional sonography and magnetic resonance imaging, might provide useful information on the early damage of testicular structure by varicoceles, therefore helping clinicians target repair efforts to those men who will benefit from varicocele treatment.

Tsili AC, Xiropotamou ON, Sylakos A, Maliakas V, Sofikitis N, Argyropoulou MI. Potential role of imaging in assessing harmful effects on spermatogenesis in adult testes with varicocele. World J Radiol 2017; 9(2): 34-45 Available from: URL: DOI:

INTRODUCTION

Male infertility is a social problem, representing the causal factor for infertility in 50% of cases and the sole cause in 30% of infertile couples[1-3]. Varicocele is the most common andrological disorder between adolescents and adult males. Its clinical significance is mainly related to fertility, as it represents the most common cause of impaired male fertility and the most common treatable cause of infertility[4-10]. The origin of the word varicocele comes from varico (a combining form meaning “varix” in Latin) and cele (a combining form meaning “tumor” in Greek) and dates to 1730-1740.

Varicocele has been one of the most controversial topics of debate in the fields of andrology and urology, regarding the effect of varicocele on male infertility and whether repair leads to improvement of fertility status[4-10]. While most men with varicocele are able to father children, most evidence suggests that varicocele has detrimental effects on male reproductive potential. A non-invasive imaging technique providing answers to questions regarding which patients with varicocele are at risk for infertility and which will benefit from varicocele repair, would be extremely useful.

DEFINITION AND EPIDEMIOLOGY

Varicocele is clinically defined as an abnormal dilation of the veins of the pampiniform venous plexus and the testicular veins with continuous or intermittent reflux of venous blood[4,5,11]. Primary varicoceles are due to venous reflux into the pampiniform plexus from the internal spermatic vein because of incontinent venous valves, and they usually occur on the left side. Secondary varicoceles are the result of increased pressure in the testicular veins, which can be related to several causes, such as hydronephrosis, abdominal and retroperitoneal neoplasms, and the so-called nutcracker phenomenon, which involves compression of the left renal vein between the superior mesenteric artery and aorta[4,12-15]. Although varicoceles are almost always more common and larger on the left side, they are bilateral in 50% of cases[14]. The uncommon, isolated right-sided varicocele always necessitates further investigation, as this finding may be associated with situs inversus or retroperitoneal malignancies[4,14].

Varicocele epidemiology is incompletely understood[14]. A clinical varicocele is found in approximately 15% of all adult males, up to 35% of infertile men and 81% of men presenting with secondary infertility. When classified according to semen analysis parameters, 12% of infertile men with normal semen analyses and 25.4% of those with abnormal results were found to have clinical varicocele[4,5,8,12,14]. This disorder may be present at birth or in young children, but the incidence substantially increases in adolescents coinciding with pubertal development[4,5,14]. The prevalence of varicocele also increases with advancing age, with an increase of approximately 10% per decade of life, probably because of the aging of venous valves[14].

An association between varicocele and varicose veins of the lower extremities and an inverse relationship between the prevalence of varicocele and body mass index have been suggested[4-16]. Hereditary factors may also play a role in the prevalence of varicocele[14,17].

ETIOLOGY AND PATHOGENESIS

The exact etiology of varicocele is still unknown, but it is probably multifactorial[4,5,12,13,18]. The cause for the high incidence of left varicocele is that the left internal spermatic vein runs vertically to drain into the ipsilateral renal vein at a right angle, when the man is in the standing position, and thus, the endoluminal pressure in the renal vein is transmitted backward, opposing flow from the internal spermatic vein. On the right side, the internal spermatic vein runs tangentially to join the inferior vena cava, resulting in less flow turbulence and back pressure in the vein and therefore in a lower incidence of venous dilation on the right side. However, Gat et al[19] reported that varicocele is mainly a bilateral disease, expressed earlier on the left side, with a right-sided venous return problem presenting in 86% of infertile men with clinically significant varicocele.

Several other theories related to the etiological factors of varicocele have been proposed, including the following: Incompetence or absence of venous valves in the spermatic veins, obstructed venous drainage, vascular contractions of the left testicular vein caused by catecholamines from the left adrenal gland and the so-called nutcracker phenomenon[4,5,12,13,18,20,21].

CLINICAL FINDINGS-CLASSIFICATION

Clinically, varicocele is characterized by an abnormal enlargement of the spermatic veins of the venous plexus, which drains the blood from the testes, associated with an anomalous intermittent or continuous backflow of blood into the plexus. In adult males, most cases are asymptomatic, often revealed during an investigation related to infertility and/or because of an unfavorable outcome of semen analysis[5]. Rarely, it may present with scrotal pain or create esthetic problems or discomfort due to the presence of significant enlargement of the scrotum[5,12].

Clinical varicocele was found to be a significant risk factor for decreased sperm count, motility and morphology in adult infertile men[22,23]. A study conducted by the World Health Organization (WHO) reported that both sperm concentration and motility were lower in men with varicocele compared to individuals without varicocele[22]. Recently, Agarwal et al[23] in a systematic review assessing the effects of varicocele on semen parameters based on the new 2010 WHO laboratory criteria for the examination of the human semen, reported that varicocele was associated with reduced sperm count, motility and morphology[23].

Physical examination represents the gold standard for the diagnosis of clinically significant varicoceles[5,8,12,24]. It is used by clinical urologists and pediatricians, consisting of palpation performed with the patient in the standing position and observation of the scrotum during the Valsalva maneuver. The classification system published by Dubin and Amelar in 1970 is the most commonly used and includes the following three degrees of varicocele: Grade 1, varicocele detectable by palpation only during the Valsalva maneuver; Grade 2, varicocele detectable by simple palpation; and, Grade 3, varicocele visible on inspection and palpation[24]. However, this system has limitations because its diagnostic accuracy is closely associated with physician’s experience. A study involving experienced andrologists and clinicians identified a significant inter-observer and intra-observer variability in the grading of varicoceles based on the above classification[12].

Histology from a testicular biopsy in men with varicocele has shown depressed spermatogenesis with maturation arrest, sloughing of the spermatogenic epithelium, profusion of Leydig cells, thickening of the tubular basement membrane and interstitial blood vessel wall with luminal narrowing, and increased deposition of interstitial fibrous tissue[25].

PATHOPHYSIOLOGY

The pathophysiology of impaired spermatogenesis in varicocele is multifactorial. A combination of several factors affects spermatogenesis and sperm function, and the relative involvement of these factors is different in each patient[4,7,8,25]. Several pathophysiologic mechanisms resulting in impairment of spermatogenesis in left varicocele have been proposed, including heat stress, notch signaling, cadmium accumulation, insufficiency of the hypothalamo-pituitary-gonadal axis, retrograde flow of adrenal or renal metabolites, possible disruptions of blood-testis barrier, testicular hypoxia and alterations in testicular extracellular fluid dynamics[4,7,8,25]. Interstitial lesions, includingthe proliferation of Leydig cells, thickening of the tubular basement membrane and blood vessel wall with luminal narrowing, and increased deposition of interstitial collagen fibers may also play an important role in varicocele-related testicular dysfunction[25].

Current evidence suggests the primary role of reactive oxygen species (ROS) and the resultant oxidative stress (OS) in the pathogenesis of varicocele-associated male infertility[4,7,8,18,25,26]. Excessive ROS has also been associated with sperm DNA fragmentation (SDF), which may mediate the clinical manifestation of poor sperm function and infertility related to varicocele[4,7,8,18,25-27]. A significantly less total acrosin activity in the spermatozoa of infertile men with varicocele and an abnormal retention of cytoplasmic droplets by human spermatozoa, which is negatively correlated with sperm motility, are other potential contributing factors for the diminished sperm function in individuals with varicocele[4,28].

Using animal models, bilateral detrimental effects on testicular temperature, blood flow, and histology have been reported to occur in cases of unilateral varicocele, probably related either to the dilatation of the right testicular vein in individuals with left varicocele or the role of the sympathetic nervous system[4,29,30]. The development of a unilateral varicocele affecting bilateral Leydig cell secretory function results in a significant reduction in bilateral intratesticular testosterone cοntent, which, in turn, affects the Sertoli cell secretory function and epididymal maturation process, all contributing to the reduced male reproductive potential[4]. Recent advances in biomolecular techniques and mass spectrometry equipment have allowed us to better understand the molecular pathways associated with varicocele and male infertility[25,31,32].

DIAGNOSIS

In the past, various diagnostic imaging modalities were used for the evaluation of varicoceles, including venography, scintigraphy, and thermography[33-35]. Labeled blood-pool scintigraphy was reported as an accurate and noninvasive method for the detection and grading of varicocele. The main contribution of radionuclide blood-pool imaging of the scrotum was in the detection and grading of subclinical varicocele in infertile men with no other cause of infertility. The technique was also accurate in the diagnosis of recurrent varicocele[33-35]. However, the above methods have been replaced by less invasive and more easily performed diagnostic tools, especially ultrasonographic examination of the scrotum.

Ultrasonography (US) is currently the most established and widely used modality for the study of varicoceles, with 97% sensitivity and 94% specificity in the diagnosis of clinical varicocele and 83%-95% sensitivity in the diagnosis of subclinical varicocele[5,12,13,33,36,37]. The classic US features of a varicocele is that of “multiple, anechoic, serpiginous, tubular structures” near the superior and lateral aspects of the testis. Color, power, or spectral Doppler US with settings optimized for low flow velocities is used complimentary to aid in the diagnosis of varicoceles. Τypical Doppler findings include venous flow at rest, with intermittent or continuous flow reversal with Valsalva maneuver (Figures 1 and 2)[5,33].

However, there are no homogeneous US criteria regarding the extent of venous dilation or reflux that must be present to meet the definition of a varicocele[5,12,13,36-45]. A widely accepted US criterion for the diagnosis of varicocele is the existence of veins larger than 2 mm in diameter, with 95% sensitivity[38]. In general, clinicians agree that clinically relevant varicoceles are more than 2.5-3 mm in diameter[33]. Multiple grading systems exist for classifying the US findings of varicocele; however, all have a low predictive value in terms of impairment of spermatogenesis, which is the main indication for any therapeutic plan[5,12,13,31,46,47]. The Sarteschi (Table 1) and Chiou et al[47] (Table 2) classifications systems are among the most commonly used.

Advances in US and magnetic resonance imaging (MRI) provide the potential to expand the role of imaging beyond that of visual confirmation and characterization of varicoceles. Τhe ability to identify the early signs of testicular dysfunction based on imaging findings may have implications for the selection of patients for varicocele repair.

US IN THE EVALUATION OF INTRATESTICULAR MICROCIRCULATION IN TESTES WITH VARICOCELE

The testis gets its arterial supply mainly from the testicular artery (TA) supplemented with the cremasteric artery and the deferential artery, all coursing through the deep inguinal canal to enter the spermatic cord[48-51]. TA penetrates the tunica albuginea along the posterior surface of the testis and divides into capsular arteries. These capsular branches then give rise to the centripetal arteries which carry blood from the capsular surface, centrally towards the mediastinum along the testicular septa. Branches of the centripetal arteries then course backward towards the capsular surface, known as recurrent rami. In approximately 50% of testes, the transtesticular artery can also be seen passing directly from the testicular artery at the mediastinum into the parenchyma[48-51]. Testicular perfusion can be evaluated with color Doppler (CD), power Doppler, and spectral Doppler US. The spectral waveform of the intratesticular arteries characteristically has a low-resistance pattern, with a mean resistive index (RI) in adults and postpubertal boys of 0.62 (range, 0.48-0.75)[48].

Several clinical studies have assessed the effects of varicocele on testicular blood flow by US[49,50-56]. In an early study, Ross et al[52] compared the testicular blood flow in 248 patients with varicocele and 34 fertile volunteers with color Doppler ultrasonography (CDUS) and reported no significant differences[52]. A similar result was reported by Grasso Leanza et al[53]. In this study, the peak systolic velocity (PSV) of the testicular arteries was evaluated in men with varicocele and healthy subjects with normal or impaired spermatogenesis using CDUS. No significant difference was found in relation to the presence or degree of varicocele[53].

However, in subsequent studies, CDUS proved to be sensitive in assessing alterations in intratesticular circulation in testes with clinical varicocele[37,49,54-56]. A significant decrease in testicular arterial blood flow and an increase in RI and PSV in testes with clinical varicocele were reported[37,49,54-56]. Semiz et al[37] concluded that spectral Doppler parameters might be used as a noninvasive method to assess the hemodynamic changes and testicular microcirculation in cases of clinical varicocele[37]. The PSV, end-diastolic velocity (EDV), RI and pulsatility index (PI) from capsular and intratesticular arteries in 50 men with clinical varicocele were measured and correlated with semen analysis parameters, including count, motility, volume and morphology. PSV significantly correlated with sperm count in men with unilateral and bilateral varicocele. No significant correlation between EDV, RI, PI and semen analysis results was found[37]. Unsal et al[54] evaluated the effects of clinical varicocele on testicular microcirculation comparing PSV, EDV, RI and PI from capsular and intratesticular arteries in 15 men with left clinical varicocele and 34 controls[54]. The authors found a significantly greater RI and PI of capsular branches of the left testes (RI = 0.68 ± 0.04; PI = 1.22 ± 0.15) compared to the control group (RI = 0.64 ± 0.06; PI = 1.07 ± 0.18)[54].